# This file is part of Hypothesis, which may be found at
# https://github.com/HypothesisWorks/hypothesis/
#
# Copyright the Hypothesis Authors.
# Individual contributors are listed in AUTHORS.rst and the git log.
#
# This Source Code Form is subject to the terms of the Mozilla Public License,
# v. 2.0. If a copy of the MPL was not distributed with this file, You can
# obtain one at https://mozilla.org/MPL/2.0/.

import copy
from typing import Any, Iterable, Tuple, overload

from hypothesis.errors import InvalidArgument
from hypothesis.internal.conjecture import utils as cu
from hypothesis.internal.conjecture.engine import BUFFER_SIZE
from hypothesis.internal.conjecture.junkdrawer import LazySequenceCopy
from hypothesis.internal.conjecture.utils import combine_labels
from hypothesis.internal.filtering import get_integer_predicate_bounds
from hypothesis.internal.reflection import is_identity_function
from hypothesis.strategies._internal.strategies import (
    T3,
    T4,
    T5,
    Ex,
    MappedStrategy,
    SearchStrategy,
    T,
    check_strategy,
    filter_not_satisfied,
)
from hypothesis.strategies._internal.utils import cacheable, defines_strategy


class TupleStrategy(SearchStrategy):
    """A strategy responsible for fixed length tuples based on heterogeneous
    strategies for each of their elements."""

    def __init__(self, strategies: Iterable[SearchStrategy[Any]]):
        super().__init__()
        self.element_strategies = tuple(strategies)

    def do_validate(self):
        for s in self.element_strategies:
            s.validate()

    def calc_label(self):
        return combine_labels(
            self.class_label, *(s.label for s in self.element_strategies)
        )

    def __repr__(self):
        tuple_string = ", ".join(map(repr, self.element_strategies))
        return f"TupleStrategy(({tuple_string}))"

    def calc_has_reusable_values(self, recur):
        return all(recur(e) for e in self.element_strategies)

    def do_draw(self, data):
        return tuple(data.draw(e) for e in self.element_strategies)

    def calc_is_empty(self, recur):
        return any(recur(e) for e in self.element_strategies)


@overload
def tuples() -> SearchStrategy[Tuple[()]]:  # pragma: no cover
    ...


@overload
def tuples(__a1: SearchStrategy[Ex]) -> SearchStrategy[Tuple[Ex]]:  # pragma: no cover
    ...


@overload
def tuples(
    __a1: SearchStrategy[Ex], __a2: SearchStrategy[T]
) -> SearchStrategy[Tuple[Ex, T]]:  # pragma: no cover
    ...


@overload
def tuples(
    __a1: SearchStrategy[Ex], __a2: SearchStrategy[T], __a3: SearchStrategy[T3]
) -> SearchStrategy[Tuple[Ex, T, T3]]:  # pragma: no cover
    ...


@overload
def tuples(
    __a1: SearchStrategy[Ex],
    __a2: SearchStrategy[T],
    __a3: SearchStrategy[T3],
    __a4: SearchStrategy[T4],
) -> SearchStrategy[Tuple[Ex, T, T3, T4]]:  # pragma: no cover
    ...


@overload
def tuples(
    __a1: SearchStrategy[Ex],
    __a2: SearchStrategy[T],
    __a3: SearchStrategy[T3],
    __a4: SearchStrategy[T4],
    __a5: SearchStrategy[T5],
) -> SearchStrategy[Tuple[Ex, T, T3, T4, T5]]:  # pragma: no cover
    ...


@overload
def tuples(
    *args: SearchStrategy[Any],
) -> SearchStrategy[Tuple[Any, ...]]:  # pragma: no cover
    ...


@cacheable
@defines_strategy()
def tuples(*args: SearchStrategy[Any]) -> SearchStrategy[Tuple[Any, ...]]:
    """Return a strategy which generates a tuple of the same length as args by
    generating the value at index i from args[i].

    e.g. tuples(integers(), integers()) would generate a tuple of length
    two with both values an integer.

    Examples from this strategy shrink by shrinking their component parts.
    """
    for arg in args:
        check_strategy(arg)

    return TupleStrategy(args)


class ListStrategy(SearchStrategy):
    """A strategy for lists which takes a strategy for its elements and the
    allowed lengths, and generates lists with the correct size and contents."""

    _nonempty_filters: tuple = (bool, len, tuple, list)

    def __init__(self, elements, min_size=0, max_size=float("inf")):
        super().__init__()
        self.min_size = min_size or 0
        self.max_size = max_size if max_size is not None else float("inf")
        assert 0 <= self.min_size <= self.max_size
        self.average_size = min(
            max(self.min_size * 2, self.min_size + 5),
            0.5 * (self.min_size + self.max_size),
        )
        self.element_strategy = elements
        if min_size > BUFFER_SIZE:
            raise InvalidArgument(
                f"{self!r} can never generate an example, because min_size is larger "
                "than Hypothesis supports.  Including it is at best slowing down your "
                "tests for no benefit; at worst making them fail (maybe flakily) with "
                "a HealthCheck error."
            )

    def calc_label(self):
        return combine_labels(self.class_label, self.element_strategy.label)

    def do_validate(self):
        self.element_strategy.validate()
        if self.is_empty:
            raise InvalidArgument(
                "Cannot create non-empty lists with elements drawn from "
                f"strategy {self.element_strategy!r} because it has no values."
            )
        if self.element_strategy.is_empty and 0 < self.max_size < float("inf"):
            raise InvalidArgument(
                f"Cannot create a collection of max_size={self.max_size!r}, "
                "because no elements can be drawn from the element strategy "
                f"{self.element_strategy!r}"
            )

    def calc_is_empty(self, recur):
        if self.min_size == 0:
            return False
        else:
            return recur(self.element_strategy)

    def do_draw(self, data):
        if self.element_strategy.is_empty:
            assert self.min_size == 0
            return []

        elements = cu.many(
            data,
            min_size=self.min_size,
            max_size=self.max_size,
            average_size=self.average_size,
        )
        result = []
        while elements.more():
            result.append(data.draw(self.element_strategy))
        return result

    def __repr__(self):
        return (
            f"{self.__class__.__name__}({self.element_strategy!r}, "
            f"min_size={self.min_size:_}, max_size={self.max_size:_})"
        )

    def filter(self, condition):
        if condition in self._nonempty_filters or is_identity_function(condition):
            assert self.max_size >= 1, "Always-empty is special cased in st.lists()"
            if self.min_size >= 1:
                return self
            new = copy.copy(self)
            new.min_size = 1
            return new

        kwargs, pred = get_integer_predicate_bounds(condition)
        if kwargs.get("len") and ("min_value" in kwargs or "max_value" in kwargs):
            new = copy.copy(self)
            new.min_size = max(self.min_size, kwargs.get("min_value", self.min_size))
            new.max_size = min(self.max_size, kwargs.get("max_value", self.max_size))
            # Unsatisfiable filters are easiest to understand without rewriting.
            if new.min_size > new.max_size:
                return SearchStrategy.filter(self, condition)
            # Recompute average size; this is cheaper than making it into a property.
            new.average_size = min(
                max(new.min_size * 2, new.min_size + 5),
                0.5 * (new.min_size + new.max_size),
            )
            if pred is None:
                return new
            return SearchStrategy.filter(new, condition)

        return SearchStrategy.filter(self, condition)


class UniqueListStrategy(ListStrategy):
    def __init__(self, elements, min_size, max_size, keys, tuple_suffixes):
        super().__init__(elements, min_size, max_size)
        self.keys = keys
        self.tuple_suffixes = tuple_suffixes

    def do_draw(self, data):
        if self.element_strategy.is_empty:
            assert self.min_size == 0
            return []

        elements = cu.many(
            data,
            min_size=self.min_size,
            max_size=self.max_size,
            average_size=self.average_size,
        )
        seen_sets = tuple(set() for _ in self.keys)
        result = []

        # We construct a filtered strategy here rather than using a check-and-reject
        # approach because some strategies have special logic for generation under a
        # filter, and FilteredStrategy can consolidate multiple filters.
        def not_yet_in_unique_list(val):
            return all(key(val) not in seen for key, seen in zip(self.keys, seen_sets))

        filtered = self.element_strategy._filter_for_filtered_draw(
            not_yet_in_unique_list
        )
        while elements.more():
            value = filtered.do_filtered_draw(data)
            if value is filter_not_satisfied:
                elements.reject(f"Aborted test because unable to satisfy {filtered!r}")
            else:
                for key, seen in zip(self.keys, seen_sets):
                    seen.add(key(value))
                if self.tuple_suffixes is not None:
                    value = (value, *data.draw(self.tuple_suffixes))
                result.append(value)
        assert self.max_size >= len(result) >= self.min_size
        return result


class UniqueSampledListStrategy(UniqueListStrategy):
    def do_draw(self, data):
        should_draw = cu.many(
            data,
            min_size=self.min_size,
            max_size=self.max_size,
            average_size=self.average_size,
        )
        seen_sets = tuple(set() for _ in self.keys)
        result = []

        remaining = LazySequenceCopy(self.element_strategy.elements)

        while remaining and should_draw.more():
            i = len(remaining) - 1
            j = data.draw_integer(0, i)
            if j != i:
                remaining[i], remaining[j] = remaining[j], remaining[i]
            value = self.element_strategy._transform(remaining.pop())

            if value is not filter_not_satisfied and all(
                key(value) not in seen for key, seen in zip(self.keys, seen_sets)
            ):
                for key, seen in zip(self.keys, seen_sets):
                    seen.add(key(value))
                if self.tuple_suffixes is not None:
                    value = (value, *data.draw(self.tuple_suffixes))
                result.append(value)
            else:
                should_draw.reject(
                    "UniqueSampledListStrategy filter not satisfied or value already seen"
                )
        assert self.max_size >= len(result) >= self.min_size
        return result


class FixedKeysDictStrategy(MappedStrategy):
    """A strategy which produces dicts with a fixed set of keys, given a
    strategy for each of their equivalent values.

    e.g. {'foo' : some_int_strategy} would generate dicts with the single
    key 'foo' mapping to some integer.
    """

    def __init__(self, strategy_dict):
        dict_type = type(strategy_dict)
        self.keys = tuple(strategy_dict.keys())
        super().__init__(
            strategy=TupleStrategy(strategy_dict[k] for k in self.keys),
            pack=lambda value: dict_type(zip(self.keys, value)),
        )

    def calc_is_empty(self, recur):
        return recur(self.mapped_strategy)

    def __repr__(self):
        return f"FixedKeysDictStrategy({self.keys!r}, {self.mapped_strategy!r})"


class FixedAndOptionalKeysDictStrategy(SearchStrategy):
    """A strategy which produces dicts with a fixed set of keys, given a
    strategy for each of their equivalent values.

    e.g. {'foo' : some_int_strategy} would generate dicts with the single
    key 'foo' mapping to some integer.
    """

    def __init__(self, strategy_dict, optional):
        self.required = strategy_dict
        self.fixed = FixedKeysDictStrategy(strategy_dict)
        self.optional = optional

    def calc_is_empty(self, recur):
        return recur(self.fixed)

    def __repr__(self):
        return f"FixedAndOptionalKeysDictStrategy({self.required!r}, {self.optional!r})"

    def do_draw(self, data):
        result = data.draw(self.fixed)
        remaining = [k for k, v in self.optional.items() if not v.is_empty]
        should_draw = cu.many(
            data, min_size=0, max_size=len(remaining), average_size=len(remaining) / 2
        )
        while should_draw.more():
            j = data.draw_integer(0, len(remaining) - 1)
            remaining[-1], remaining[j] = remaining[j], remaining[-1]
            key = remaining.pop()
            result[key] = data.draw(self.optional[key])
        return result
